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Our immune system is made of various cell types responsible for fighting pathogens and disease that enter the body. There are two distinct arms or responses of the immune system: innate and adaptive. The innate immune response is the first line of defense that includes immune cells that are not specific to the invading pathogen, but recognize it is foreign and tries to kill it. Cells that are included in this response are neutrophils, basophils, eosinophils, monocytes, macrophages, mast cells, and natural killer cells. The adaptive immune response is the second line of defense and made up of cells that are more specific to the invading pathogen. The adaptive immune system includes dendritic cells, T cells, and B cells. T cells specifically have different subsets and function differently to effectively kill invading pathogens.

Although scientists know a lot about the immune system, there is still much unknown about how the cells that make up these immune responses completely function. One unclear phenomenon includes the mechanism by which immune cells know which way to travel to the site of infection. Researchers lead by Drs. Michael Sixt and Edouard Hannezo at the Institute of Science and Technology Austria (ISTA) recently reported in Science Immunology that immune cells generate their own path to navigate environments throughout the body.

One particular immune cell type, dendritic cells, are not exclusively part of the adaptive immune system. They work to bridge the innate and adaptive immune systems to help cohesively deliver a response that will efficiently kill the pathogen. More specifically, dendritic cells detect pathogens and then travel to the lymph nodes to coordinate a systemic attack. Dendritic cells move according to chemokines, or small proteins that help cells migrate to specific locations. Previously, it was believed that the chemokines produce a gradient and it was this gradient that allowed cells to migrate to specific locations. However, Sixt, Hannezo, and colleagues reported that this gradient might not be the only way for migrating cells.

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Lenovo’s next 27-inch 4K monitor is unlike any display it has released before. Featuring a lenticular lens and real-time eye-tracking, it’s a 3D monitor that doesn’t require any glasses. Other companies are already pushing stereoscopic products, but Lenovo’s ThinkVision 27 3D Monitor, announced at the IFA conference today, takes the glasses-free experience to a bigger screen.

The technology behind Lenovo’s 3D monitor and the accompanying software, 3D Explorer, are proprietary, a Lenovo spokesperson confirmed to Ars. 3D Explorer includes a 3D player and SDK for building 3D apps. Lenovo is targeting the monitor and app at content creators, like 3D graphic designers and developers.

Like other glasses-less 3D screens, the ThinkVision works by projecting two different images to each of your eyes, resulting in a 3D effect where, as PR images would have you believe, it appears that the images are popping out of the screen. Lenovo says the monitor’s 3D resolution is 1920×2160. The lenticular lens in the monitor is switchable, allowing for normal, 2D viewing at 3840×2160, too.

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This post is also available in: he עברית (Hebrew)

Ukraine’s security agency claims that the Russian military intelligence service GRU can access compromised Android devices with a new malware called Infamous Chisel, which is associated with the threat actor Sandworm, previously attributed to the Russian GRU’s Main Centre for Special Technologies (GTsST).

Sandworm uses this new malware to target Android devices used by the Ukrainian military, enables unauthorized access to compromised devices, and is designed to scan files, monitor traffic, and steal information.

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CAPE CANAVERAL, Fla. (AP) — Four astronauts from four countries rocketed toward the International Space Station on Saturday.

They should reach the orbiting lab in their SpaceX capsule Sunday, replacing four astronauts living up there since March.

A NASA astronaut was joined on the predawn liftoff from Kennedy Space Center by fliers from Denmark, Japan and Russia. They clasped one another’s gloved hands upon reaching orbit.

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Non-perturbative interactions (i.e., interactions too strong to be described by so-called perturbation theory) between light and matter have been the topic of numerous research studies. Yet the role that quantum properties of light play in these interactions and the phenomena arising from them have so far remained widely unexplored.

Researchers at Technion–Israel Institute of Technology recently introduced a new describing the physics underpinning non-perturbative interactions driven by . Their theory, introduced in Nature Physics, could guide future experiments probing strong-field physics phenomena, as well as the development of new quantum technology.

This recent paper was the result of a close collaboration between three different research groups at Technion, led by principal investigators Prof. Ido Kaminer, Prof. Oren Cohen and Prof. Michael Krueger. Students Alexey Gorlach and Matan Even Tsur, co-first authors of the paper, spearheaded the study, with support and ideas from Michael Birk and Nick Rivera.

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